Nanoporous, Gas Permeable PEGDA Ink for 3D Printing Organ‐on‐a‐Chip Devices

Abstract Polydimethylsiloxane (PDMS), commonly used in organ‐on‐a‐chip (OoC) systems, faces limitations in replicating complex geometries, hindering its effectiveness in creating 3D OoC models. In contrast, poly(ethylene glycol)diacrylate (PEGDA‐250), favored for its fabrication ease and resistance to small molecule absorption, is increasingly used for 3D printing microfluidic devices. However, applications in cell culture have been limited due to poor cell adhesion. Here, a nanoporous PEGDA ink (P‐PEGDA) is introduced to enhance cell adhesion. P‐PEGDA is formulated with a porogen, photopolymerized, followed by the porogen removal. Utilizing P‐PEGDA, complex microstructures, and membranes as thin as 27 µm are 3D‐printed. Porogen concentrations from 10 to 30% are tested yielding constructs with increasing porosity and oxygen permeability surpassing PDMS, without compromising printing resolution. Tests across four cell lines show >80% cell viability, with a notable 77‐fold increase in MDA‐MB‐231 cell coverage on the porous scaffolds. Finally, an OoC model comprising a gyroid scaffold with a central opening filled with a cancer spheroid is introduced. This setup, after a 14 days co‐culture, demonstrates significant endothelial sprouting and integration within the spheroid. The P‐PEGDA formulation is suitable for high‐resolution 3D printing of constructs for 3D cell culture and OoC owing to its printability, gas permeability, biocompatibility, and cell adhesion.